Abstract
The stationary Boussinesq equations describing the heat transfer in the viscous heat-conducting fluid under inhomogeneous Dirichlet boundary conditions for velocity and mixed boundary conditions for temperature are considered. The optimal control problems for these equations with tracking-type functionals are formulated. A local stability of the concrete control problem solutions with respect to some disturbances of both cost functionals and state equation is proved.
1. Introduction
Much attention has been recently given to the optimal control problems for thermal and hydrodynamic processes. In fluid dynamics and thermal convection, such problems are motivated by the search for the most effective mechanisms of the thermal and hydrodynamic fields control [1–4]. A number of papers are devoted to theoretical study of control problems for stationary models of heat and mass transfer (see e.g., [5–19]). A solvability of extremum problems is proved, and optimality systems which describe the necessary conditions of extremum were constructed and studied. Sufficient conditions to the data are established in [16, 18, 19] which provide the uniqueness and stability of solutions of control problems in particular cases.
Along with the optimal control problems, an important role in applications is played by the identification problems for heat and mass transfer models. In these problems, unknown densities of boundary or distributed sources, coefficients of model differential equations, or boundary conditions are recovered from additional information of the original boundary value problem solution. It is significant that the identification problems can be reduced to appropriate extremum problems by choosing a suitable tracking-type cost functional. As a result, both control and identification problems can be studied using an unified approach based on the constrained optimization theory in the Hilbert or Banach spaces (see [1–4]).
The main goal of this paper is to perform an uniqueness and stability analysis of solutions to control problems with tracking-type functionals for the steady-state Boussinesq equations. We shall consider the situation when the boundary or distributed heat sources play roles of controls and the cost functional depends on the velocity. Using some results of [2] we deduce firstly the optimality system for the general control problem which describes the first-order necessary optimality conditions. Then, based on the optimality system analysis, we deduce a special inequality for the difference of solutions to the original and perturbed control problems. The latter is obtained by perturbing both cost functional and one of the functions entering into the state equation. Using this inequality, we shall establish the sufficient conditions for data which provide a local stability and uniqueness of solutions to control problems under consideration in the case of concrete tracking-type cost functionals.
The structure of the paper is as follows. In Section 2, the boundary value problem for the stationary Boussinesq equations is formulated, and some properties of the solution are described. In Section 3, an optimal control problem is stated, and some theorems concerning the problem solvability, validity of the Lagrange principle for it, and regularity of the Lagrange multiplier are given. In addition, some additional properties of solutions to the control problem under consideration will be established. In Section 4, we shall prove the local stability and uniqueness of solutions to control problems with the velocity-tracking cost functionals. Finally, in Section 5, the local uniqueness and stability of optimal controls for the vorticity-tracking cost functional is proved.
2. Statement of Boundary Problem
In this paper we consider the model of heat transfer in a viscous incompressible heat-conducting fluid. The model consists of the Navier-Stokes equation and the convection-diffusion equation for temperature that are nonlinearly related via buoyancy in the Boussinesq approximation and via convective heat transfer. It is described by equations Here is a bounded domain in the space , with a boundary consisting of two parts and ; , , and denote the velocity and temperature fields, respectively; , where is the pressure and is the density of the medium; is the kinematic viscosity coefficient, is the gravitational acceleration vector, is the volumetric thermal expansion coefficient, is the thermal conductivity coefficient, is a given vector-function on , is a given function on a part of , is a function given on another part of , is the unit outer normal. We shall refer to problem (2.1)–(2.3) as Problem 1. We note that all quantities in (2.1)–(2.3) are dimensional and their dimensions are defined in terms of SI units.
We assume that the following conditions are satisfied:(i) is a bounded domain in , , with Lipschitz boundary , consisting of coupled components , ; and meas .
Below we shall use the Sobolev spaces and , where , or and for the vector functions where denotes , its subset , or a part of the boundary . In particularly we need the function spaces , , , , and their subspaces
The inner products and norms in , , or are denoted by , , , , or , . The inner products, norms and seminorms in and are denoted by , , and or , and if . The norms in or are denoted by or ; the norm in the dual space is denoted by . Set . Let in addition to condition (i) the following conditions hold:(ii), , .
The following technical lemma holds (see [2, 20]).
Lemma 2.1. Under conditions (i) there exist constants , , , , and such that Bilinear form satisfies the inf-sup condition Besides the following identities take place:
Let , , , in addition to (i), (ii). We multiply the equations in (2.1), (2.2) by test functions and and integrate the results over with use of Green's formulas to obtain the weak formulation for the model (2.1)–(2.3). It consists of finding a triple satisfying the relations
Following theorem (see [2]) establishes the solvability of Problem 1 and gives a priori estimates for its solution.
Theorem 2.2. Let conditions (i), (ii) be satisfied. Then Problem 1 has for every quadruple , , , a weak solution that satisfies the estimates Here , and are nondecreasing continuous functions of the norms , , , , , , . If, additionally, are small in the sense that where , , , and are constants entering into (2.5)–(2.7), then the weak solution to Problem 1 is unique.
3. Statement of Control Problems
Our goal is the study of control problems for the model (2.1)–(2.3) with tracking-type functionals. The problems consist in minimization of certain functionals depending on the state and controls. As the cost functionals we choose some of the following ones: Here is a subdomain of . The functionals , , and where functions (or ) and are interpreted as measured velocity or vorticity fields are used to solve the inverse problems for the models in questions [2].
In order to formulate a control problem for the model (2.1)–(2.3) we split the set of all data of Problem 1 into two groups: the group of controls containing the functions , , and , which play the role of controls and the group of fixed data comprising the invariable functions , and . As to the function entering into the boundary condition for the velocity in (2.3), it will play peculiar role since the stability of solutions to control problems under consideration (see below) will be studied with respect to small perturbations, both the cost functional and the function in the norm of .
Let , . Denote by a weakly lower semicontinuous functional. We assume that the controls , , and vary in some sets , , . Setting , , , we introduce the functional by the formula Here are nonnegative parameters which serve to regulate the relative importance of each of terms in (3.2) and besides to match their dimensions. Another goal of introducing parameters is to ensure the uniqueness and stability of the solutions to control problems under study (see below).
We assume that following conditions take place:(iii), , are nonempty closed convex sets;(iv), or , and is a bounded set, .
Considering the functional at weak solutions to Problem 1 we write the corresponding constraint which has the form of the weak formulation (2.13)–(2.15) of Problem 1 as follows: Here is the operator acting by formulas The mathematical statement of the optimal control problem is as follows: to seek a pair , where and such that
Let and be the duals of the spaces and . Let denotes the Fréchet derivative of with respect to at the point . By we denote the adjoint operator of which is determined by the relation According to the general theory of extremum problems (see [21]) we introduce an element which is referred to as the adjoint state and define the Lagrangian , where , by Here and below , and is an auxiliary dimensional parameter. Its dimension is chosen so that dimensions of at the adjoint state coincide with those at the basic state, that is, Here denote the SI dimensions of the length, time, mass, and temperature units expressed in meters, seconds, kilograms, and degrees Kelvin, respectively. As a result , and can be referred to below as the adjoint velocity, pressure, and temperature. Simple analysis shows (see details in [16]) that the necessity for the fulfillment of (3.8) is that is given by .
The following theorems (see, e.g., [2]) give sufficient conditions for the solvability of control problem (3.5), the validity of the Lagrange principle for it, and a regularity condition for a Lagrange multiplier.
Theorem 3.1. Let conditions (i)–(iv) hold and . Then there exists at least one solution to problem (3.5) for , .
Theorem 3.2. Let under conditions of Theorem 3.1 a pair be a local minimizer in problem (3.5) and let the cost functional be continuously differentiable with respect to at the point . Then there exists a nonzero Lagrange multiplier such that the Euler-Lagrange equation for the adjoint state is satisfied and the minimum principle holds which is equivalent to the inequality
Theorem 3.3. Let the assumptions of Theorem 3.2 be satisfied and condition (2.17) holds for all . Then any nontrivial Lagrange multiplier satisfying (3.9) is regular, that is, has the form and is uniquely determined.
We note that the functional and Lagrangian given by (3.7) are continuously differentiable functions of controls and its derivatives with respect to , and are given by Here for example is the Gateaux derivative with respect to at the point . Since are convex sets, at the minimum point of the functional the following conditions are satisfied (see [22]):
We also note that the Euler-Lagrange equation (3.9) is equivalent to identities Relations (3.13), the minimum principle which is equivalent to the inequalities (3.10) or (3.12), and the operator constraint (3.3) which is equivalent to (2.13)–(2.15) constitute the optimality system for control problem (3.5).
Theorems 3.1 and 3.2 above are valid without any smallness conditions in relation to the data of Problem 1. The natural smallness condition (2.17) arises only when proving the uniqueness of solution to boundary problem (2.1)–(2.3) and Lagrange multiplier regularity. However, condition (2.17) does not provide the uniqueness of problem (3.5) solution. Therefore, an investigation of problem (3.5) solution uniqueness is an interesting and complicated problem. Studying of its solution stability with respect to small perturbations of both cost functional entering into (3.2) and state equation (3.3) is also of interest. In order to investigate these questions we should establish some additional properties of the solution for the optimality system (2.13)–(2.15), (3.12), (3.13). Based on these properties, we shall impose in the next section the sufficient conditions providing the uniqueness and stability of solutions to control problem (3.5) for particular cost functionals introduced in (3.1).
Let us consider problem (3.5). We assume below that the function entering into (2.3) can vary in a certain set . Let be an arbitrary solution to problem (3.5) for a given function . By we denote a solution to problem It is obtained by replacing the functional in (3.5) by a close functional depending on and by replacing a function by a close function .
By Theorem 3.1 the following estimates hold for triples : Here where , , and are introduced in Theorem 3.1. We introduce “model” Reynolds number , Raley number , and Prandtl number by They are analogues of the following dimensionless parameters widely used in fluid dynamics: the Reynolds number Re, the Rayleigh number Ra, and the Prandtl number Pr. We can show that the parameters introduced in (3.17) are also dimensionless if , , and (where is an arbitrary scalar) are defined as Here is a dimensional factor of dimension whose value is equal to 1.
Assume that the following condition takes place:
Let us denote by , where , , Lagrange multipliers corresponding to solutions . By Theorems 3.2 and 3.3 and (3.12) they satisfy relations We renamed , in (3.20). Set , , , , , , and Let us subtract (2.13)–(2.15), written for from (2.13)–(2.15) for , , , , . We obtain We set , , in the inequality (3.23) under and , , in the same inequality under and add. We obtain
Subtract the identities (3.20)–(3.22), written for from the corresponding identities for ,, set , and add. Using (3.27) we obtain Set further in (3.25), in (3.26), and subtract obtained relations from (3.29). Using inequality (3.28) and arguing as in [18], we obtain Thus we have proved the following result.
Theorem 3.4. Let under conditions of Theorem 3.2 for functionals and and condition (3.19) quadruples and be solutions to problem (3.5) under and problem (3.14) under , respectively, , be corresponding Lagrange multipliers. Then the inequality (3.30) holds for differences , defined in (3.24), where , .
Below we shall need the estimates of differences , , entering into (3.25)–(3.27) by differences , , , and . Denote by a vector such that in , , . Here is a constant depending on . The existence of follows from [20, page 24]. We present the difference as , where is a new unknown function. Set , in (3.25). Taking into account (2.9) we obtain Using estimates (2.5), (2.6), (2.7), and (3.15), we deduce from (3.31) that
It follows from (3.19) that Rewriting the inequality (3.32) by (3.33) as we obtain that Taking into account the relation , we come to the following estimate via and :
Denote by a function such that and the estimate holds with a certain constant , which does not depend on . Let us present the difference as , where is a new unknown function. Set , in (3.26). We obtain Using estimates (2.5)–(2.8) and (3.15) we deduce that or Taking into account the relation , we obtain from this estimate that
Using further the estimate (3.36) for , we deduce from (3.40) that From this inequality and (3.17), (3.19) we come to the following estimate:
Using (3.42), we deduce from (3.36) that Taking into account (3.17) we come to the following estimate for :
An analogous estimate holds and for the pressure difference . In order to establish this estimate we make use of inf-sup condition (2.10). By (2.10) for the function and any (small) number there exists a function , , such that where . Set in the identity for in (3.25) and make of this estimate and estimates (2.6), (2.7), (3.15). We shall have Dividing to , we deduce that Using (3.42) and (3.44), we come to the following final estimate for :
Remark 3.5. Along with three-parametric control problem (3.5) we shall consider and one-parametric control problem which corresponds to situation when a function is a unique control. This problem can be considered as particular case of the general control problem (3.5), for which the set consists of one element and the set consists of one element . For this case the conditions , take place, and the estimates (3.42)–(3.47) and inequality (3.30) take the form
4. Control Problems for Velocity Tracking-Type Cost Functionals
Based on Theorem 3.4 and estimates (3.42)–(3.47) or (3.48)–(3.50), we study below uniqueness and stability of the solution to problem (3.5) for concrete tracking-type cost functionals. We consider firstly the case mentioned in Remark 3.5 where and the heat flux on the part of is a unique control; that is, we consider one-parametric control problem In accordance to Remark 3.5 we can consider problem (4.1) as a particular case of the general control problem (3.5), which corresponds to the situation when every of sets and consists of one element.
Let be a solution to problem (4.1), that corresponds to given functions and , and let be a solution to problem (4.1), that corresponds to perturbed functions and . Setting in addition to (3.24) we note that under conditions of problem (4.1) we have Identity (3.22) for problem (4.1) does not change, while identities (3.20), (3.21), and inequality (3.51) take due to (4.2) a form
Using identities (4.3), (4.4), (3.22) we estimate parameters , , and . Firstly we deduce estimates for norms and . To this end we set , in (4.3), (3.22). Taking into account (2.11), (2.12), and condition , which follows from (4.4), we obtain Using estimates (2.5)–(2.8) and (3.15) we have where
By virtue of (4.8)–(4.10) and (4.12), we deduce from (4.7) and (4.6) that Taking into account (4.14), we obtain from (4.15) that Using (3.33) we deduce successfully from (4.16), (4.14) that
Let us estimate further the norms and from (4.3). In order to estimate we make use of inf-sup condition (2.10). By (2.10) for a function and any small number there exists a function , , such that the inequality holds. Setting in (4.3) and using this estimate together with estimates (2.6), (3.15), (4.11), we have From this inequality we deduce by (4.17) that Taking into account (4.17), we come from (4.20) to the estimate
It remains to estimate . To this end we make again use of identity (4.3). Using estimates (2.6), (2.9) and (3.15), (4.11), (4.17), (4.21) as well we have As we obtain from this inequality that
Taking into account (2.6), (3.48), (3.49), and estimates (4.17) for , , we have It follows from (4.24) that Here constants and are given by
Let the data for problem (4.1) and parameters , be such that with a certain constant the following condition takes place: Under condition (4.27) we deduce from (4.25) that Taking into account (4.28) and the estimate which follows from (4.23), we come from (4.5) to the inequality It follows from this inequality that Excluding nonpositive term from the right-hand side of (4.30), we deduce from (4.30) that
Equation (4.31) is a quadratic inequality for . Solving it we come to the following estimate for : As , , , the estimate (4.32) is equivalent to the following estimate for the velocity difference : This estimate under has the sense of the stability estimate in of the component of the solution to problem (4.1) relative to small perturbations of functions and in the norms of and , respectively. In particular case where the estimate (4.33) transforms to “exact” a priori estimate . It was obtained when studying control problems for Navier-Stokes and in [18] when studying control problems for heat convection equations. If besides it follows from (4.33) that in , if . This yields together with (4.30), (3.48), (3.50) that , , . The latter means the uniqueness of the solution to problem (4.1) when and condition (4.27) holds.
It is important to note that the uniqueness and stability of the solution to problem (4.1) under condition (4.27) take place and in the case where ; that is, is only a part of domain . In order to prove this fact let us consider the inequality (4.30). Using (4.32) we deduce from (4.30) that From (4.34) and (3.48)–(3.50) we come to the following stability estimates: where Thus we have proved the theorem.
Theorem 4.1. Let, under conditions (i), (ii), (iii) for and (3.19), the quadruple be a solution to problem (4.1) corresponding to given functions and , , where is an arbitrary open subset, and let the parameters and , are defined in (4.23) and (4.26) in which parameters and are given by (4.13). Suppose that condition (4.27) is satisfied. Then stability estimates (4.33) and (4.35)–(4.38) hold true where is defined in (4.39).
Now we consider three-parametric control problem corresponding to the cost functional . Let be a solution to problem (4.40) corresponding to given functions and , and let be a solution to problem (4.40) corresponding to perturbed functions and . Setting in addition to (3.24), we note that under conditions of problem (4.40) identities (3.20) and (3.21) transform to identities (4.3), (4.4), identity (3.22) does not change, while inequality (3.30) takes by (4.2) a form
From (4.3), (4.4), and (3.22) we come to the same estimates (4.17), (4.21), and (4.23) for norms , , and . Taking into account these estimates and estimates (3.42), (3.44) for , , we deduce that Here parameters and are given by (4.13). From (4.42) we obtain that Here constants , , , and are given by relations
Let the data for problem (4.40) and parameters , , , and be such that Under condition (4.45) we deduce from (4.43) that Taking into account (4.46) and (4.23), we come from (4.41) to the inequality It follows from this inequality that Excluding nonpositive terms from the right-hand side of (4.48), we come to the inequality (4.31) where constants and are defined in (4.23) and (4.44). From (4.31) we deduce the estimate (4.32) for with mentioned constants and given by (4.23) and (4.44). As in the case of problem (4.1), stability in the norm of the component of the solution to problem (4.40) relative to small perturbations of functions and in the norms of and , respectively, and uniqueness of the solution to problem (4.40) follow from (4.32) in the case when and (4.45) holds.
We note again that the uniqueness and stability of the solution to problem (4.40) under condition (4.45) take place and in the case where is only a part of the domain . In order to establish this fact we consider inequality (4.48) which we rewrite taking into account (4.32) as From this inequality and from (3.42)–(3.47) we come to the following stability estimates: Here a constant depending on , , and is given by and a quantity is defined in (4.39). Thus the following theorem is proved.
Theorem 4.2. Let, under conditions (i), (ii), (iii), and (3.19), an element , be a solution to problem (4.40) corresponding to given functions and , where is an arbitrary open subset, and let parameters and be defined in (4.23) and (4.44), where and are given by (4.13). Suppose that conditions (4.45) are satisfied. Then stability estimates (4.33) and (4.50)–(4.53) hold where and are defined in (4.39) and (4.54).
In the same manner one can study control problem corresponding to the cost functional . Let us denote by a solution to problem (4.55) which corresponds to given functions and ; by we denote a solution to problem (4.1) which corresponds to perturbed functions and . Setting in addition to (3.24) we note that under conditions of problem (4.55) we have Identity (3.22) for problem (4.1) does not change while identities (3.20), (3.21) and inequality (3.51) transform by (4.56) to (4.4) and relations
Using identities (4.57), (4.4), and (3.22) we estimate parameters , , and . To this end we set , in (4.57), (3.22). Taking into account (2.11), (2.12) and condition which follows from (4.4) we obtain (4.7) and relation Using estimates (3.15) we deduce in addition to (4.8)–(4.10) that where Proceeding further as above in study of problem (4.1) we come to the estimates for , , and . They have a form (4.17), (4.21), and (4.23), where parameters and are given by (4.61).
Let us assume that the condition (4.27) takes place where parameter is defined in (4.26), (4.61). Using (4.27) and estimates (4.17), (4.21), (4.23) we deduce inequality (4.28) where parameter is given by relations (4.26), (4.61). Taking into account (4.28) and (4.23), we come from (4.58) to the inequality It follows from this inequality that Excluding nonpositive term , we deduce from (4.63) that Equation (4.31) is a quadratic inequality relative to . By solving it we come to the estimate which is equivalent to the following estimate for : The estimate (4.66) under has the sense of the stability estimate in the norm of the component of the solution to problem (4.55) relative to small perturbations of functions and in the norms of and respectively. In the case where and it follows from (4.66) that in , if . This yields together with (4.63), (3.48), (3.50) that , , . The latter means the uniqueness of the solution to problem (4.55) when and (4.27) holds.
We note again that using (4.63), (4.65) we can deduce rougher stability estimates of the solution to problem (4.55) which take place even in the case where . In fact we deduce from (4.63) (4.65) that From (4.67) and (3.48)–(3.50) we come to the estimates (4.35)–(4.38) where one should set
Thus we have proved the following theorem.
Theorem 4.3. Let, under conditions (i), (ii), (iii) for and (3.19), the quadruple be a solution to problem (4.55) corresponding to given functions and , , where is an arbitrary open subset, and let parameters , , be defined in (4.23) and (4.26), in which and are given by (4.61). Suppose that condition (4.27) is satisfied. Then the stability estimates (4.66) and (4.35)–(4.38) hold where is defined in (4.68).
In the similar way one can study three-parametric control problem It is obtained from (4.40) by replacing of the cost functional by . Analogous analysis shows that the following theorem holds.
Theorem 4.4. Let, under conditions (i), (ii), (iii) and (3.19), an element be a solution to problem (4.69) corresponding to given functions and , , where is an arbitrary open subset and let parameters and are defined in (4.23) and (4.26), in which and are given by (4.61). Suppose that conditions (4.45) are satisfied. Then the stability estimates (4.66) and (4.50)–(4.53) hold where is defined in (4.68).
5. Control Problem for Vorticity Tracking-Type Cost Functional
Consider now one-parametric control problem which corresponds to the cost functional . Let be a solution to problem (5.1) corresponding to given functions and , and let be a solution to problem (4.1) corresponding to perturbed functions and . Setting in addition to (3.24), we have under conditions of problem (4.1) Identity (3.22) for problem (5.1) does not change, while identities (3.20), (3.21) and inequality (3.51) transform due to (5.2) to (4.4) and relations
Using identities (5.3), (3.22), (4.4) we estimate parameters , , , and . Firstly we deduce estimates of norms and . To this end we set , in (5.3), (3.22). Taking into account (2.11), (2.12) and condition , which follows from (4.4), we obtain (4.7) and relation Using (2.9), (3.15) we deduce in addition to (4.8)–(4.10) that where Arguing as above in analysis of problem (4.1) we come to the same estimates (4.17), (4.21), and (4.23) for , , , and in which parameters and are given by (5.7).
Let us assume that the condition (4.27) takes place where parameter is defined in (4.26), (5.7). Using (4.27) and (4.17), (4.21), (4.23) we deduce inequality (4.28) where parameter is given by (4.26), (5.7). Taking into account (4.28) and (4.23) with parameter defined in (4.23), (5.7) we come from (5.4) to the inequality It follows from this inequality that Excluding nonpositive term , we deduce from (5.9) that Equation (5.10) is a quadratic inequality relative to . Solving it we come to the estimate which is equivalent to the following estimate for the difference :
The estimate (5.12) under has the sense of the stability estimate in the norm of the vorticity of the component of the solution to problem (5.1) relative to small perturbations of functions and in the norms of and , respectively. In particular case where and it follows from (5.11) that in , if . From this relation and from (4.30), (3.48), (3.50) it follows that , , . The latter means the uniqueness of the solution to problem (4.1) when and condition (4.27) holds.
If we can deduce from (5.11) and (5.9) rougher stability estimates of the solution to problem (5.1), which are analogous to estimates (4.35)–(4.38). In fact using (5.11) we deduce from (5.9) that From (5.13) and (3.48)–(3.50) we come to the estimates (4.35)–(4.38) where Thus the following theorem is proved.
Theorem 5.1. Let, under conditions (i), (ii), (iii) for and (3.19), the quadruple , be a solution to problem (5.1) corresponding to given functions and , , where is an arbitrary open subset, and let parameters and , be defined in relations (4.23) and (4.26), in which and are given by (5.7). Suppose that condition (4.27) is satisfied. Then the stability estimates (5.12) and (4.35)–(4.38) hold true where is defined in (5.14).
In the similar way one can study three-parametric control problem It is obtained from (4.40) by replacing the cost functional by . The following theorem holds.
Theorem 5.2. Let, under conditions (i), (ii), (iii), and (3.19), an element , be a solution to problem (5.15) corresponding to given functions and , , where is an arbitrary open subset, and let parameters and be given by relations (4.23) and (4.44), in which and be defined in (5.7). Suppose that conditions (4.45) are satisfied. Then the stability estimates (5.12) and (4.50)–(4.53) hold where and are defined in (5.14) and (4.54).
6. Conclusion
In this paper we studied control problems for the steady-state Boussinesq equations describing the heat transfer in viscous heat-conducting fluid under inhomogeneous Dirichlet boundary conditions for velocity and mixed boundary conditions for temperature. These problems were formulated as constrained minimization problems with tracking-type cost functionals. We studied the optimality system which describes the first-order necessary optimality conditions for the general control problem and established some properties of its solution. In particular we deduced a special inequality for the difference of solutions to the original and perturbed control problem. The latter is obtained by perturbing both the cost functional and the boundary function entering into the Dirichlet boundary condition for the velocity. Using this inequality we found the group of sufficient conditions for the data which provide a local stability and uniqueness of concrete control problems with velocity-tracking or vorticity-tracking cost functionals. This group consists of two conditions: the first is the same for all control problems and has the form of the standard condition (3.19) which ensures the uniqueness of the solution to the original boundary value problem for the Boussinesq equations. The second one depends on the form of control problem under study. In particular for the one-parametric problem (4.1) corresponding to velocity-tracking functional it has the form of estimates (4.27) of the parameters and included in (4.1), while for the three-parametric problem (4.40) it has the form of estimates (4.45) of the parameters , , , and included in (4.40). Similar conditions take place for another tracking-type functionals.
On the one hand, conditions (4.27) and (4.45) are similar to the uniqueness and stability conditions for the solution to the coefficient identification problems for the linear convection-diffusion-reaction equation. On the other hand, these conditions contain compressed information on the Boussinesq heat transfer model (2.1), (2.2) in the form of the constant defined in (4.26) for problem (4.1) or in the form of three constants , , defined in (4.44) for problem (4.40). An analysis of the expressions for or , , shows that for fixed values of the parameters inequality (4.27) or inequalities (4.45) represent additional constraints on the Reynolds number , Rayleigh number , and Prandtl number which together with (3.19) ensure the uniqueness and stability of the solution to problem (4.1) or (4.40). We also note that for fixed values of , , and inequalities (4.27) and (4.45) imply that to ensure the uniqueness and stability of the solution to problem (4.1) or (4.40) the values of the parameters , , and should be positive and exceed the constants on the right-hand sides of inequalities (4.27) and (4.45). This means that the term in the expression for minimized functional in (4.1) or the terms , and in the expression for minimized functional in (4.40) have a regularizing effect on the control problem under consideration. The same conclusions hold true and for another control problems studied in this paper.
Acknowledgments
This work was supported by the Russian Foundation for Basic Research (Project no. 10-01-00219-a) and the Far East Branch of the Russian Academy of Sciences (Project no. 09-I-P29-01).